1. Rittal White Paper 305:
Selecting Air Conditioners for
Industrial Enclosures
By: Judith Koetzsch
Mark Corcoran, Editor
Executive Summary
Choosing the right air conditioners for enclosures can have a tremendous impact on the overall
performance and efficiency of industrial operations. Proper and efficient air conditioner cooling can
significantly prolong the life of installed equipment, save energy and utility costs, and protect against
unscheduled downtime. Although cooling is sometimes an afterthought during the course of planning a
project at the enclosure layout level, with careful consideration and the right information, it can truly
become an asset for increased productivity and profitability.
This paper identifies different factors that should be considered when choosing air conditioners for
industrial enclosures including internal heat loads, the various methods used to rate the cooling capacity
of enclosure air conditioners, the impact of humidity and other ambient conditions, and energy
efficiency. Understanding air conditioner performance diagrams and sizing tools in relation to application
requirements is also covered.

2. Factors to Consider
Internal Heat Load
The internal heat load is the amount of heat energy produced by the electronics inside the
enclosure, and it comes from the unused electricity running through the components. In order to
specify the right air conditioner capacity for an application, it is critical to know the amount of
heat energy (in BTU per hour or in Watts) that will be created by the equipment housed within
the enclosure.
How to Determine the Amount of Heat Energy to be Removed?
There are multiple ways to determine the heat load inside an enclosure. One way is to add up
the heat loads of all of the installed electronic components as specified by the component
manufacturers as seen below.
Example:
Device Heat load as specified by the manufacturer
20 HP Drive 1500 Watts
1250 A Circuit breaker 200 Watts
PLC 5 A 3 Watts
Transformer 1000 VA 64 Watts
Total 1667 Watts
Another approach is to add up the electricity consumed by the electronics and then multiply it by
the efficiency of the system. The resulting number equals the need for cooling capacity. For
example, if an electronics system is consuming 500 Watts of power and it is 20% efficient, the
system is only using 100 Watts of electricity for its actual function. The remaining 400 Watts is
dissipated in the form of heat energy.
Impacting Cooling Capacity
In the world of electronics, cooling capacity is the maximum amount of thermal energy that a
climate control product can remove, and it is shown either in Watts or BTU per hour (if
necessary, to convert Watts into BTU per hour, multiply by 3.413). The cooling capacity, or
performance, of a specific enclosure air conditioner not only depends on its overall design, but
also on various application-specific factors. These factors include the ambient temperature, the
maximum allowable internal temperature, and the operating frequency (in Hz).
The ambient temperature (Ta) can significantly affect the cooling capacity of an air conditioner. If
an air conditioner operates in high ambient temperatures (for example, the maximum operating
temperature for Rittal TopTherm air conditioners is 131° F), it provides less cooling capacity.
This is because air conditioners work by pulling the hot air from inside the electrical enclosure
and transferring the thermal energy away from the cabinet to the surrounding environment. The
hotter the outside air is, the ability of the air conditioner to transfer the enclosure heat energy out
through the condenser coil is diminished. As to be expected, the opposite is true when air
conditioners are placed in areas with lower ambient temperatures since the heat transfer
through the condenser coil into the ambient air is quicker, consequently raising the cooling
capacity of the air conditioner.
The maximum allowable internal temperature (Ti) is also relevant to the cooling capacity of an
air conditioner because it determines how much thermal energy needs to be removed from an
enclosure and can vary from application to application. Typically, air conditioners operate by
maintaining temperatures that do not exceed a specified set point. A recommended set point for
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3. enclosure air conditioners lies between 86° F and 104° F, depending on the electronics installed
in the enclosure. Lower temperature set points can easily lead to excessive condensation and
should be avoided.
Example:
The set point of an air conditioner is set to 95° F and the differential (or switching hysteresis)
setting is 9° F. The temperature inside the enclosure is allowed to increase to 95° F before the
air conditioner starts to run to cool the temperature down to 86° F. Now that the differential to
the set point has been reached, the air conditioner shuts off until the enclosure temperature
rises to the set point of 95° F again.
The third factor that influences the cooling capacity of an air conditioner is the operating
frequency. Here in North America, 60 Hz is the norm, but throughout much of the world, 50 Hz
is used. This is why, for example, most Rittal TopTherm Plus air conditioner models are dual-
rated, meaning that they can operate at both 50 and 60 Hz. A dual rating allows for the same air
conditioner to be used all over the world where different power systems supply different
frequencies. When an air conditioner is operating at 60 Hz, the fans and compressor actually
rotate faster than at 50 Hz, resulting in higher performance for the air conditioner at 60 Hz.
When evaluating an air conditioner stated to have a certain cooling capacity, it’s important to
consider under what temperature conditions, and at which operating frequency, that cooling
capacity is provided.
Why Some Manufacturers Determine Cooling Capacity Differently than Others
In North America, no formal standard for testing or publishing cooling capacity exists, so most
manufacturers use the maximum temperatures at which the air conditioner is designed to
operate as reference points (maximum internal and external temperatures). The maximum
operating temperatures can differ between air conditioner models as well as manufacturers.
Typically, a maximum operating temperature is at 131° F. If indicated, the rating temperatures
could be shown as L131/L131 or Ti 95/Ta 95 or 95° F/95° F. Traditionally the first number
stands for the internal temperature.
In Europe, a standard called DIN 3168/EN 814 part 500 (European standard for enclosure
climate control) is used. This standard levels the playing field, and provides a more realistic
measure of performance, by requiring all manufacturers to use the same temperature conditions
to determine cooling capacity—allowing users to make true one-to-one comparisons.
Since Rittal is a global supplier of enclosure air conditioners, the cooling capacities shown on its
units comply with existing standards.
Helpful Tools
Air Conditioner Performance Diagrams
To determine the cooling capacity of an air conditioner under the above-described variable
conditions, a performance diagram can be used. These charts show the cooling capacity of an
air conditioner per the requirements of DIN 3168, as well as under different temperature
scenarios—including maximum operating conditions. This will help users to determine how a
particular air conditioner will perform in a specific application.
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4. Air Conditioner Sizing
When selecting an air conditioner, the easiest way to figure out how an air conditioner will
perform at given temperatures is to use sizing software. These convenient tools typically walk
users through the various factors that impact an application, and then determine the need for
cooling. Rittal’s Therm 5.14 sizing software, for example, can calculate what the internal
enclosure temperature would be without any means of cooling before predicting how many BTU
or Watts of cooling capacity the application requires and suggesting an appropriate part
number.
Calculating Air Conditioner Efficiency
Reducing power consumption and increasing efficiency are vitally important to protecting the
environment, and to saving money during the operation of air conditioners at the end user level.
The formula to determine the efficiency of an air conditioner (shown below) is simple—it’s the
ratio between useful cooling capacity and power consumption. The higher the cooling efficiency
factor, the more efficient the air conditioner is.
Example:
Enclosure Air Conditioner: 460 V, 60 Hz
Cooling capacity at 95/95, 60 Hz: 2700 Watt
Power consumption at 95/95, 60 Hz: 1500 Watt
Cooling efficiency factor = 2700 Watt
1500 Watt
Cooling efficiency factor = 1.8
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5. Calculating the Impact of Humidity
An unavoidable side effect of using air conditioners is the dehumidification of the enclosure’s
interior air. As it cools down, part of the humidity contained in the air condenses on the
evaporator coil. The reliable discharge of this condensate from the enclosure is important to
consider, and is achieved by using condensate hoses and collection bottles in conventional
units, or via condensate evaporators in more advanced products like Rittal’s TopTherm PLUS.
The amount of condensate that is created depends on relative humidity, the air temperature in
the enclosure, the evaporator coil, and the air volume present in the enclosure. The Mollier h-x
diagram (see next page) is used to show the water content of air depending on its temperature
and relative air humidity.
Calculation Example:
An enclosure air conditioner has a temperature set point of Ti = 95° F. The relative ambient air
humidity is 70%. If 95° F air is exchanged over the evaporator coil, the surface temperature of
the evaporator coil (evaporation temperature of the refrigerant) is approximately 64° F. At the
outer layer, adhering to the surface of the evaporator coil, water (condensate) is deposited at
the dew point. The difference, Δx = x1 – x2, indicates the amount of condensation that occurs
per 2.2 lb of air with complete dehumidification. How airtight an enclosure is plays an important
role in the amount of condensation that will occur in an application. Since the quantity of
ambient air (and as a result, the amount of humidity) is limited in a properly sealed enclosure,
the amount of condensation will be limited too.
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6. Application Example Using Mollier h-x Diagram (above):
Equation: W = V · ρ · Δx
where:
W = Water quantity in grams
V = Volume in m3
ρ = Density of the air in kg/m3
Δx = Difference in water content in g/kg dry air (from the Mollier h-x diagram)
Enclosure door closed, ambient air is not entering the enclosure—
only the humidity trapped inside of the enclosure is being dehumidified.
V = W · H · D = 0.6 m · 2 m · 0.5 m
V = 0.6 m3
W = V · ρ · Δx
= 0.6 m3
· 1.2 kg/m3
· 11 g/kg
W = 7.92 g 8 ml.
If placed into the same calculation example above, an enclosure that is not properly sealed will
see more condensation. Ambient (humid) air can enter through poorly sealed cable entries,
damaged or open enclosure doors, and damaged enclosure gaskets—resulting in increased
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7. condensation. If, for example, ambient air is entering the enclosure at a rate of 5 m3
/h, a
permanent condensation amount of 2.7 oz/h (80ml/h) may occur.
Because of this, it’s always recommended that control panels be operated with enclosure doors
closed and that all sides of the enclosure are properly sealed and gasketed. In addition, it is
advisable to use a door switch that interrupts the operation of the air conditioner while the
enclosure door is open and to set the internal temperature of the enclosure only as low as is
actually needed.
Conclusions
Selecting the right air conditioner for an industrial enclosure application is crucial to maximizing
efficiency, performance, and overall return on investment. Knowing what factors to consider,
and taking the time to properly evaluate the products available, can save money by reducing
utility costs, drastically improve the life and reliability of installed equipment, and solidify
operations as a whole through increased productivity and limiting unplanned downtime.
About the Author
Judith Koetzsch has been with Rittal since 2001—first working for Rittal GmbH & Co. Kg. in
Germany as a part of the international climate control product management team, and then
joining Rittal Corporation in the U.S. as Product Manager for Climate Control Products in 2006.
The Rittal Corporation is the U.S. subsidiary of Rittal GmbH & Co. KG and manufactures the world’s leading industrial and IT enclosures, racks
and accessories, including climate control, power management and electronic packaging systems for industrial, data center, outdoor and hybrid
applications.
1 Rittal Place • Urbana, OH 43078 • Toll free: 800-477-4000 • Website: www.rittal-corp.com
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